Optimal Conditions for Treating Acid Mine Drainage by Bentonite-Steel Slag Composites

Liping Xiao, W. Bin, Jichi Bai, Liu Zhe
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Abstract

The Acid Mine Drainage has characteristics of low pH, high concentrations of heavy metal ions, such as Fe 2+ , Mn 2+ , Cu 2+ and Zn 2+ . In this paper, the composite particles that consisted of bentonite and steel slags were used to dispose the Acid Mine Drainage. Bentonite is the mineral materials and can adsorb heavy metal ions excellently. The steel slags are alkaline and industrial solid waste for the treatment of the Acid Mine Drainage. The main influencing factors, such as adsorbent dosages, shaking rates, concentrations of heavy metal ions, temperatures, adsorption time and pH value were studied by the static experiment. Increasing the adsorbent dosages and the concentrations of the heavy metal ions, speeding up the shaking rates, raising the temperatures, extending the adsorption time and improving pH would improve the removal efficiencies of heavy metal ions. Through considering the removal efficiencies and the treatment costs, the optimum reaction conditions for the four kinds of heavy metal ions were obtained. The adsorbent dosage 21 mg/L, the rotational speed 120 r / min, the temperature 25℃, adsorption time 100 min and the initial wastewater pH 7. The four kinds of heavy metal ions existed independently in the simulated mine wastewater. The highest initial concentrations of Fe 2+ , Mn 2+ , Cu 2+ and Zn 2+ were 150 mg/L, 100 mg/L, 170 mg/L and 140 mg/L respectively. The removal rates were 93.42%, 92.64%, 93.86% and 95.17% respectively. The determination of the particles’ SEM-EDS Microscopic characterization showed the composite particles could play a part in neutralizing, absorbing and the chemical precipitation. The acidity decreased notably and the heavy metal ions of Fe 2+ , Mn 2+ , Cu 2+ and Zn 2+ were adsorbed and precipitated effectively. The research results can extend the practical engineering application of the composite particles.
膨润土-钢渣复合材料处理酸性矿井水的最佳工艺条件
酸性矿山水具有pH值低、重金属离子(Fe 2+、Mn 2+、Cu 2+、Zn 2+)浓度高的特点。本文采用膨润土与钢渣复合颗粒处理酸性矿山废水。膨润土是一种矿物材料,对重金属离子有很好的吸附作用。钢渣是酸性矿山废水处理的碱性工业固体废物。通过静态实验研究了吸附剂用量、摇摇速率、重金属离子浓度、温度、吸附时间和pH值等主要影响因素。增加吸附剂投加量和重金属离子浓度、加快振荡速度、提高吸附温度、延长吸附时间和改善pH值可以提高重金属离子的去除效率。通过对去除率和处理成本的综合考虑,得出了四种重金属离子的最佳反应条件。吸附剂用量21 mg/L,转速120 r / min,温度25℃,吸附时间100 min,初始废水pH为7。四种重金属离子在模拟矿山废水中独立存在。Fe 2+、Mn 2+、Cu 2+和Zn 2+的最高初始浓度分别为150 mg/L、100 mg/L、170 mg/L和140 mg/L。去除率分别为93.42%、92.64%、93.86%和95.17%。粒子的SEM-EDS表征表明复合粒子具有中和、吸收和化学沉淀的作用。酸度明显降低,Fe 2+、Mn 2+、Cu 2+、Zn 2+等重金属离子被有效吸附和沉淀。研究结果可拓展复合颗粒的实际工程应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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